CN103718276A - Method of stabilizing hydrogenated amorphous silicon and amorphous hydrogenated silicon alloys - Google Patents
Method of stabilizing hydrogenated amorphous silicon and amorphous hydrogenated silicon alloys Download PDFInfo
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- CN103718276A CN103718276A CN201280035916.XA CN201280035916A CN103718276A CN 103718276 A CN103718276 A CN 103718276A CN 201280035916 A CN201280035916 A CN 201280035916A CN 103718276 A CN103718276 A CN 103718276A
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- deuterium
- amorphous silicon
- hydrogenated amorphous
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- 238000000034 method Methods 0.000 title claims abstract description 73
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- 230000000087 stabilizing effect Effects 0.000 title 1
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- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/0248—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by their semiconductor bodies
- H01L31/036—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by their semiconductor bodies characterised by their crystalline structure or particular orientation of the crystalline planes
- H01L31/0376—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by their semiconductor bodies characterised by their crystalline structure or particular orientation of the crystalline planes including amorphous semiconductors
- H01L31/03762—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by their semiconductor bodies characterised by their crystalline structure or particular orientation of the crystalline planes including amorphous semiconductors including only elements of Group IV of the Periodic Table
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- H01L31/0216—Coatings
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- H01L31/04—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices
- H01L31/06—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices characterised by potential barriers
- H01L31/075—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices characterised by potential barriers the potential barriers being only of the PIN type, e.g. amorphous silicon PIN solar cells
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Abstract
A method of forming a semiconductor material of a photovoltaic device that includes providing a surface of a hydrogenated amorphous silicon containing material, and annealing the hydrogenated amorphous silicon containing material in a deuterium containing atmosphere. Deuterium from the deuterium-containing atmosphere is introduced to the lattice of the hydrogenated amorphous silicon containing material through the surface of the hydrogenated amorphous silicon containing material. In some embodiments, the deuterium that is introduced to the lattice of the hydrogenated amorphous silicon containing material increases the stability of the hydrogenated amorphous silicon containing material.
Description
Background
Present disclosure relates to amorphous silicon hydride (α-Si:H) and alloy thereof.Present disclosure further relates to and comprises the photovoltaic device that is incorporated to amorphous silicon hydride wherein, for example solar cell.Amorphous silicon hydride can be used for producing solar cell and transistor device.
Example is the p-i-n solar cell as the assembly of individual devices or many knot (series connection) batteries, and has the heterojunction solar battery of single crystalline Si (c-Si) absorbed layer.Use other example of the structure of amorphous silicon hydride to comprise the passivation layer of photovoltaic cell, and for the thin-film transistor of display and x-ray imaging device.In addition, hydrogenated amorphous silicon alloys, for example hydrogenated amorphous SiGe and hydrogenated amorphous silicon carbide are also for p-i-n solar cell and heterojunction solar battery.
General introduction
In one embodiment, the method that forms amorphous silicon hydride (α-Si:H) and/or α-Si:H alloy is provided, and it is introduced deuterium (D) in the lattice of α-Si:H and/or α-Si:H alloy to replace at least one silicon-hydrogen (Si-H) key with at least one silicon-deuterium (Si-D) key.In some embodiments, by replacing at least one silicon-hydrogen (Si-H) key with at least one silicon-deuterium (Si-D) key, can improve the stability of amorphous silicon hydride (α-Si:H) and/or α-Si:H alloy.In one embodiment, this method comprises the surface that containing hydrogenated amorphous silicon (α-Si:H) material is provided, with by containing hydrogenated amorphous silicon (α-Si:H) material containing annealing in deuterium atmosphere, wherein deuterium is introduced in the lattice of containing hydrogenated amorphous silicon (α-Si:H) material.
The photovoltaic device of the material that comprises containing hydrogenated amorphous silicon and deuterium is provided at present disclosure on the other hand.In one embodiment, the material of containing hydrogenated amorphous silicon and deuterium comprises and is greater than 80 atom % (atom %) silicon, is greater than 5 atom % hydrogen and is greater than 0.001 atom % deuterium.In one embodiment, deuterium can be with unsettled silicon key bonding to compare the stability of the material that improves containing hydrogenated amorphous silicon and deuterium with the amorphous silicon hydride that does not contain deuterium.
Accompanying drawing summary
As an example and the disclosure following detailed description that is not intended to be limited to this together with accompanying drawing, can understand best, wherein similarly reference number represents similar element and parts, wherein:
Fig. 1 is for setting forth the diagram of hydrogen regulation and control weak bond model.
Fig. 2 is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises unijunction p-i-n solar cell, and wherein at least one layer of material of photovoltaic device is comprised of the material of containing hydrogenated amorphous silicon and deuterium.
Fig. 3 is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises binode p-i-n solar cell, and wherein at least one layer of material of photovoltaic device is comprised of the material of containing hydrogenated amorphous silicon and deuterium.
Fig. 4 is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises three knot p-i-n solar cells, and wherein at least one layer of material of photovoltaic device is comprised of the material of containing hydrogenated amorphous silicon and deuterium.
Fig. 5 A is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises heterojunction solar battery, projectile configuration or passivation layer that described heterojunction solar battery has monocrystalline silicon (c-Si) absorbed layer and is comprised of the material of containing hydrogenated amorphous silicon and deuterium.
Fig. 5 B is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises heterojunction solar battery, the projectile configuration that described heterojunction solar battery has monocrystalline silicon (c-Si) absorbed layer and is comprised of the material of containing hydrogenated amorphous silicon and deuterium, wherein transparent conductive material is overlapped in projectile configuration and exists.
Fig. 6 is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises heterojunction solar battery, and described heterojunction solar battery has front and rear heterojunction contacts.
Fig. 7 is according to present disclosure embodiment, the cross-sectional side view of the photovoltaic device that comprises heterojunction solar battery, and described heterojunction solar battery has two emitters.
Fig. 8 is according to present disclosure embodiment, the cross-sectional side view of tandem photovoltaic device, and described tandem photovoltaic device comprises the upper cell that the material by containing hydrogenated amorphous silicon and deuterium forms and the bottom battery being comprised of crystal semiconductor material.
Fig. 9 is according to present disclosure embodiment, all has the cross-sectional side view of crystalline silicon (c-Si) sheet of amorphous silicon hydride (α-Si:H) passivation layer on c-Si sheet both sides.
Figure 10 is for for comprising with the photovoltaic device with the hydrogenated amorphous silicon layer of structure described in Fig. 9 of deuterium gas annealing in process and comprising the photovoltaic device with the amorphous silicon hydride of structure described in Fig. 9 with formation gas annealing (forming gas anneal) sample pretreating, and the efficient carrier life-span is with respect to the figure of annealing temperature.
Figure 11 is for for comprising with the photovoltaic device with the hydrogenated amorphous silicon layer of structure described in Figure 10 of deuterium gas annealing in process and comprising with the photovoltaic device with the amorphous silicon hydride of structure described in Figure 10 that forms gas annealing sample pretreating, and effective minority carrier lifetime is with respect to the figure of the annealing time at 100 ℃.
Figure 12 is for for comprising with the photovoltaic device with the hydrogenated amorphous silicon layer of structure described in Fig. 9 of deuterium gas annealing in process and comprising with the photovoltaic device with the amorphous silicon hydride of structure described in Fig. 9 that forms gas annealing sample pretreating, under the luminous intensity of approximately 5 daylight at room temperature effective minority carrier lifetime with respect to the figure of time.
Figure 13 (a) and 13 (b) they are after (a) 200 ℃ and (b) HPD processes at 350 ℃, for sample described in embodiment 1 and 2, and the SIMS depth analysis curve of hydrogen and deuterium in a-Si:H and a-Si:H/c-Si interface.
Describe in detail
Herein disclosed is the detailed embodiment of described structure and method; Yet, being to be understood that disclosed embodiment is only the elaboration of described structure and method, it can be summarized with various forms.In addition, the embodiment providing about each embodiment is intended for separately illustrative and is not restrictive.In addition, figure may not be pro rata, and some features can amplify to show the details of specific components.Therefore, concrete structure disclosed herein and function detail should not be construed as determinate, but as instruction those skilled in the art, diversely use the representative basis of the method and structure of present disclosure.
Be to be understood that when the element as layer, region or matrix be described as another element " on " or when " top ", can directly can there is intervention element in it on another element or also.On the contrary, when element is described as " directly on another element " or " directly above another element ", there is not intervention element.It should also be understood that and be described as " connection " or " coupling " on another element time when element, it can directly connect or be coupled on another element and maybe can have intervention element.On the contrary, when element is described as " directly connect " or " directly coupling " on another element time, there is not intervention element.
In specification, mentioning of " embodiment ", " embodiment ", " typical embodiments " etc. represents that described embodiment can comprise special characteristic, structure or characteristic, but each embodiment may not comprise special characteristic, structure or characteristic.In addition, this class phrase may not refer to identical embodiment.In addition, when special characteristic, structure or characteristic and an embodiment are described relatively, think this feature, structure or the characteristic that those skilled in the art's known effect is relevant with other embodiment, no matter whether clearly describe.
Present disclosure relates to amorphous silicon hydride (α-Si:H) and alloy thereof, and comprises the photovoltaic device that is incorporated to amorphous silicon hydride wherein, for example solar cell.One of long-standing problem that hydrogenated amorphous silicon device is common is the metastability of amorphous silicon hydride.Metastability refers to by changing the reversible variation of the material property that the variations in temperature of Fermi level (chemical potential) position in material or external excitation order about as light or skew.Conventionally, metastability is not the phenomenon of wanting, because sub-steady change changes into the deteriorated of device performance in operating time process.An example of sub-stabilization be operating period (under daylight) amorphous silicon hydride solar battery efficiency deteriorated, be called Staebler-Wronski effect, and operating period (under grid voltage partially) hydrogenation non crystal silicon film transistor (TFT) threshold voltage shift.Other phenomenon that can be produced by the metastability of amorphous silicon hydride comprises that space charge has defect that threshold currents causes to produce, the upper amorphous silicon hydride passivation of crystalline silicon (c-Si) deteriorated during the sub-steady change of doping efficiency and illumination.
In at least some cases, in amorphous silicon hydride, the source of metastability is that weak (strain) silicon-silicon bond reversibly changes into dangling bonds, and it can be described as weak bond model.The metastability of amorphous silicon hydride can be connected in the dispersion diffusion of hydrogen, and wherein (i) hydrogen can be discharged by silicon-hydrogen bond, (ii) diffuses to adjacent weak silicon-silicon bond,
(iii) by breaking weak silicon-silicon bond, produce dangling bonds.Fig. 1 has set forth hydrogen regulation and control weak bond model, and wherein hydrogen atom moves and breaks weak silicon-silicon bond from silicon-hydrogen bond, leaves two defect DH and DW.
On the one hand, present disclosure provides by deuterium (D) being introduced in hydrogenated amorphous silicon crystal lattice to replace with silicon-deuterium (Si-D) key the stability that some silicon-hydrogen bonds improve amorphous silicon hydride.Therefore, metastability is because following reason is suppressed: (i) compare with si-h bond stronger silicon-deuterium key and/or (ii) deuterium compare lower diffusivity with hydrogen.In one embodiment, the method of improving the stability of amorphous silicon hydride photovoltaic material comprises the surface of the material that containing hydrogenated amorphous silicon is provided, with by the material of containing hydrogenated amorphous silicon containing annealing in deuterium atmosphere, wherein deuterium is introduced in the lattice of material of containing hydrogenated amorphous silicon.By deuterium being introduced in the lattice of material of containing hydrogenated amorphous silicon, the material of containing hydrogenated amorphous silicon and deuterium is provided, wherein deuterium and unsettled silicon key bonding with containing the amorphous silicon hydride of deuterium, do not compare the stability of the material that improves containing hydrogenated amorphous silicon and deuterium.The key that " raising stability " means in amorphous silicon hydride destroys rate reduction, therefore suppresses above-mentioned metastability phenomenon.Therein hydrogenated amorphous Si for by monocrystalline or poly semiconductor as an embodiment of Si, Ge, SiGe or GaAs surface passivation, the result that suppresses metastability be with the sub-steady change in efficient carrier life-span in the above-mentioned crystal of the material passivation of containing hydrogenated amorphous silicon and deuterium or polycrystalline material with the similar material that does not contain the amorphous silicon hydride passivation of deuterium, compare reduction.The efficient carrier life-span in crystal or polycrystalline semiconductor material is depended on the surface restructuring speed of (on the interface with hydrogenated amorphous Si) charge carrier on carrier lifetime in the body of crystal or polycrystalline semiconductor material and crystal or polycrystalline semiconductor material surface.Surface restructuring speed and the charge carrier recombination rates on this interface on interface are proportional.Therefore, with comprising minimizing containing the sub-steady change in efficient carrier life-span in the crystal of the material passivation of the hydrogenated amorphous Si of deuterium or polycrystalline material, represent that crystal or polycrystalline material compare reduction with the material containing the containing hydrogenated amorphous Si of deuterium not with comprising containing the sub-steady change of the charge carrier recombination rates on the interface between the material of the hydrogenated amorphous Si of deuterium.As represented that for describing the term " amorphous " of the material of containing hydrogenated amorphous silicon and deuterium silane lattice lacks long-range order.Term " hydrogenation " represents that intrinsic amorphous silane contains hydrogen.The hydrogen content of amorphous silicon hydride is greater than 5 atom % conventionally, and the hydrogen content of approximately 10 atom % is the most common." containing deuterium " means amorphous silicon hydride and comprises deuterium, and wherein typical deuterium content is greater than 1 atom %.In whole the disclosure content, the possibility that film can contain crystalline portion is contained in the use of term " amorphous silicon hydride ".This is also applicable to the material of containing hydrogenated amorphous silicon, for example hydrogenated amorphous SiGe and hydrogenated amorphous silicon carbide.
Fig. 2 has described an embodiment of photovoltaic device 50, the material that wherein at least a portion photovoltaic device 50 comprises containing hydrogenated amorphous silicon and deuterium.As used herein, " photovoltaic device " for when be exposed to radiation as light lower time produce free electron-hole to and cause the device of generation current as solar cell.Photovoltaic device comprises the layer with p-type electric-conducting and N-shaped conductivity conventionally, and it shares interface so that knot to be provided.
Described in Fig. 2, embodiment is that unijunction solar cell and its base electronic structure being comprised of amorphous or microcrystal silicon (Si) is p-i-n knot.P-i-n knot comprises p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped semiconductor layer 30." intrinsic semiconductor layer " is substantially pure semiconductor material layer, and intrinsic semiconductor layer is not with N-shaped or the doping of p-type dopant.As used herein, " p-type " refers to that impurity adds in intrinsic semiconductor, and this produces the shortage (being hole) of valence electron.In operation, p-i-n knot provides electric field in response to irradiation material.Negative electrical charge is accumulated in a part of intrinsic layer of p-type electric-conducting semiconductor layer 20 and p-type side (due to ionization acceptor impurity or electropositive defect), and positive charge is accumulated in a part of intrinsic layer of N-shaped conductive semiconductor layer 30 and N-shaped side (because ionization is to body or negative defect), from N-shaped conductive semiconductor layer 30, the direction towards p-type electric-conducting semiconductor layer 20 produces electric field.Electronics in intrinsic semiconductor layer 25 is because electric field is shifted to N-shaped conductive semiconductor layer 30, and p-type electric-conducting semiconductor layer 20 is shifted in the hole in intrinsic semiconductor layer 25.Therefore, electron-hole pair systematically connects to provide positive charge and the negative electrical charge in N-shaped conductive semiconductor layer 30 on p-type electric-conducting semiconductor layer 20.P-i-n knot forms the core of this class photovoltaic device, and this provides electromotive force that can driving element.
Typically, with n-i-p inverted configuration, conventionally use p-i-n structure.This be because: in amorphous silicon hydride, the mobility of electronics can be than a hole large 1-2 order of magnitude, and the collection rate that therefore moves to the electronics of N-shaped conductive semiconductor layer 30 contacts from p-type electric-conducting semiconductor layer 20 compares that from p-type electric-conducting semiconductor layer 20, to move to the hole of N-shaped conductive semiconductor layer 30 better.Therefore, p-type electric-conducting semiconductor layer 20 should be placed towards the upper surface of the stronger photovoltaic device of luminous intensity, and making most of electric charge carrier of tying is electronics.
With reference to figure 2, photovoltaic device 50 can comprise the material heap of matrix 5, oxycompound passivation layer 10, transparent conductive material layer 15, p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25, N-shaped conductive semiconductor layer 30 and back contact metallization structure 35 from top to bottom.In one embodiment, at least one material by containing hydrogenated amorphous silicon and deuterium in p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and the N-shaped conductive semiconductor layer 30 of the p-i-n of photovoltaic device 50 knot provides.The heap of material shown in Fig. 2 provides unijunction p-i-n solar cell, discusses now its details in more detail.
Matrix 5 is for providing the structure of mechanical carrier to photovoltaic device 50.Matrix 5 is transparent within the scope of the electromagnetic radiation of the photogenerated in the interior generation electronics of photovoltaic device 50 and hole.In one embodiment, matrix 5 can, for optically transparent, be transparent in the visible electromagnetic spectrum scope that is 400-800nm at wavelength.In one embodiment, matrix 5 can be glass matrix.The thickness of matrix 5 can be 50 μ m-3mm, but also can use less and larger thickness.
Within the scope of electromagnetic radiation when transparent conductive material layer 15 is included in the photogenerated that electronics and hole occur in photovoltaic device structure, it is transparent material.For example, transparent conductive material layer 15 can comprise transparent conductive oxide (TCO), for example tin oxide (the SnO of fluorine doping
2: F), zinc oxide (ZnO:Al) or the tin indium oxide of aluminium doping.The thickness of transparent conductive material layer 15 can be 100nm-3 μ m, but also can use less and larger thickness.In one embodiment, oxycompound passivation layer 10 is present between transparent conductive material layer 15 and matrix 5.Oxycompound passivation layer 10 can be by silicon dioxide (SiO
2) form and can there is the thickness of 100nm-1 μ m, but also can use less and larger thickness.
P-i-n structure can be present in below transparent conductive material layer 15, and comprises p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 30.At least one deck of p-i-n structure can be comprised of the containing hydrogenated amorphous silicon providing as present disclosure and the material of deuterium.Because the material of containing hydrogenated amorphous silicon and deuterium has the absorptivity higher than crystalline element, spectrum can be absorbed by very thin containing hydrogenated amorphous silicon and the material layer of deuterium substantially completely.For example, the material of containing hydrogenated amorphous silicon and deuterium can have the luminous energy band gap of 1.7eV and have the optical absorption coefficient α that is greater than 105cm-1, is greater than the photon of band gap for energy.The film of the containing hydrogenated amorphous silicon that in one embodiment, only 1 μ m is thick and the material of deuterium can absorb 90% available solar energy.
Conventionally, in amorphous p-i-n structure, the hydrogen that amorphous silicon hydride comprises 5-20%, the dangling bonds passivation that wherein hydrogen produces the coordination defect in hydrogenated amorphous Si (, with respect to 4 times of coordinate crystal structures of Si, lacking or unnecessary Si atom).Yet the intensity of hydrogen silicon key is limited, and hydrogen has light weight quality, and this can promote free hydrogen to diffuse through silicon crystal lattice to break hydrogen silicon bonding.If external excitation source provides enough energy to break weak Si-Si key, hydrogen atom can depart from Si-H key, and spreads to form new Si-H key to the Si-Si key of breaking, as schematically shown in Fig. 1.This can be created in the dangling bonds at original Si-H key (it loses H atom now) position and at another dangling bonds at the Si-Si key position of breaking (note in two Si atoms one not with H bonding).These two dangling bonds are expressed as DH and DW in Fig. 1.Other reaction of same type is also possible.For example, because hydrogen discharges from the 2nd Si – H key, can weak bond is saturated with two hydrogen atoms.If H atom is non-availability when Si-Si key breaks, Si-Si key can form (substantially with hot form, dissipating, i.e. lattice vibration) again except after deexcitation.The in the situation that of throwing light on (Staebler-Wronski effect) in solar cell, the energy that a little less than breaking, the required energy of Si-Si key mainly discharges by the electron-hole pair restructuring by photogenerated provides.In the situation that the inclined to one side grid voltage in thin-film transistor, breaking the required energy of weak Si-Si key mainly provides by being trapped in by field induction free electron the energy that in dangling bonds, (coordination defect) discharges.Because D-Si key is than Si-H key is stronger and/or the diffusivity of D in Si lattice is lower than H, when D atom is used in Si-Si key and breaks due to external excitation, the saturated possibility (possibility that therefore, key breaks) of weak Si-Si key is lower.
At least one deck in p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 30 can be comprised of the material of containing hydrogenated amorphous silicon and deuterium.In at least one deck in p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 30, containing hydrogenated amorphous silicon used and the material of deuterium form by being greater than 80 atom % silicon, being greater than 5 atom % hydrogen and being greater than 0.001 atom % deuterium.In one embodiment, deuterium is present in the material of containing hydrogenated amorphous silicon and deuterium with the amount of 0.001-1 atom %.In one embodiment, hydrogen is present in the material of containing hydrogenated amorphous silicon and deuterium with the amount of 5-20 atom %.In one embodiment, silicon is present in the material of containing hydrogenated amorphous silicon and deuterium with the amount of 80-95 atom %.
The dopant that the p-type electric-conducting of p-type electric-conducting semiconductor layer 20 is provided can be the element of the III-A family from the periodic table of elements.The example of p-type dopant includes but not limited to boron, aluminium, gallium and indium, but points out that any impurity that produces valence electron shortage is suitable for p-type dopant.In one embodiment, the material that p-type electric-conducting semiconductor layer 20 comprises containing hydrogenated amorphous silicon and deuterium, it has 10
16-10
21individual atom/cm
3p-type concentration of dopant, and there is the thickness of 1-50nm.In another embodiment, in p-type electric-conducting semiconductor layer 20, the concentration of p-type dopant is 10
18-10
20individual atom/cm
3, and there is the thickness of 3-30nm.The doping efficiency of layer in 20 ratio of total dopant atom (the activated dopants atom with) is 0.1-20%, but higher and lower doping efficiency is possible.Conventionally, doping efficiency reduces by improving dopant atom concentration.Conventionally, the band gap of p-type electric-conducting semiconductor layer 20 is 1.7-2.5eV, but also can use higher and lower band gap.Layer 20 can be comprised of carbon alloy.In some embodiments, layer 20 comprises containing deuterium p-type hydrogenated amorphous silicon carbide.
One deck in intrinsic semiconductor layer 25, N-shaped conductive semiconductor layer 30 is in some embodiments that the material of containing hydrogenated amorphous silicon and deuterium forms therein, and p-type electric-conducting semiconductor layer 20 can be comprised of as crystallite (c-Si) and/or amorphous silicon hydride the material containing crystalline silicon that does not comprise deuterium.
Not by intrinsic semiconductor layer 25 use N-shapeds or the doping of p-type dopant.Between the functional period that is combined in solar cell of p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 25, set up electric field with separate electronic-hole pair.These layers also determine the voltage of device.The active layer that intrinsic semiconductor layer 25 is device, produces most solar cell electric currents there.
One deck in p-type electric-conducting semiconductor layer 20, N-shaped conductive semiconductor layer 30 is in some embodiments that the material of containing hydrogenated amorphous silicon and deuterium forms therein, and intrinsic semiconductor layer 25 can be comprised of as crystallite (c-Si) and/or amorphous silicon hydride the material containing crystalline silicon that does not comprise deuterium.
The dopant that the N-shaped conductivity of N-shaped conductive semiconductor layer 30 is provided can be the element of periodic table of elements III-A family.The example of N-shaped dopant includes but not limited to antimony, arsenic and phosphorus.Point out that above-mentioned dopant is only for illustration purpose and be not intended to limit present disclosure, because N-shaped dopant can be for producing any impurity of free electron in intrinsic semiconductor, described intrinsic semiconductor provides the basis material of N-shaped conductive semiconductor layer 30, for example the material of containing hydrogenated amorphous silicon and deuterium.In one embodiment, the material that N-shaped conductive semiconductor layer 30 comprises containing hydrogenated amorphous silicon and deuterium, it has 10
16-10
21individual atom/cm
3n-shaped concentration of dopant and there is the thickness of 1-50nm.In another embodiment, in N-shaped conductive semiconductor layer 30, the concentration of N-shaped dopant is 10
18-10
20individual atom/cm
3, and N-shaped conductive semiconductor layer 30 has the thickness of 3-30nm.The doping efficiency of layer in 20 ratio of total dopant atom (the activated dopants atom with) is 0.1-20%, but higher and lower doping efficiency is possible.Conventionally, doping efficiency reduces by improving dopant atom concentration.Conventionally, the band gap of N-shaped conductive semiconductor layer 30 is 1.6-1.8eV, but also can use higher and lower band gap.
At least one deck in intrinsic semiconductor layer 25 and p-type electric-conducting semiconductor layer 20 is in some embodiments that the material of containing hydrogenated amorphous silicon and deuterium forms therein, N-shaped conductive semiconductor layer 30 can be by forming as crystallite (c-Si) containing the material of crystalline silicon, or N-shaped conductive semiconductor layer 20 is comprised of the amorphous silicon hydride that does not comprise deuterium.
Still, with reference to figure 2, back contact metallization structure 35 comprises metal material.Metal material can have high reflectance within the scope of the electromagnetic radiation of the photogenerated in the interior generation electronics of photovoltaic device 50 and hole.Metal material can comprise silver, aluminium or its alloy.The thickness of back contact metallization structure 35 can be 100nm-1 μ m, but also can use less and larger thickness.In one embodiment, back contact metallization structure 35 serves as the negative nodal point of photovoltaic device, and transparent conductive material layer 10 can serve as the positive node of photovoltaic device 50.In some embodiments, transparent conductive material and high-reflectivity metal can be used for forming layer 35 as silver-colored bilayer, to improve reflectivity.In these embodiments, the thickness that transparent conductive material directly contacted and had common 70-100nm with layer 30.Identical with about described in layer 15 of the description of transparent conductive material.
In some embodiments, the method for photovoltaic device 50 shown in formation Fig. 2 can start to form transparent conductive material layer 25 in matrix 5.
Transparent conductive material layer 15 is used deposition process as sputter or chemical vapour deposition (CVD) formation conventionally.Chemical vapour deposition (CVD) is for deposition species is wherein due to the deposition process that between gas reactant, the chemical reaction under room temperature or higher temperature forms, and wherein the solid product of reaction is deposited on the surface of film, coating or layer of solid product to be formed.
The example that is suitable for forming the CVD method of transparent conductive material layer 15 includes but not limited to atom piezochemistry steam deposition (APCVD), low pressure chemical steam deposition (LPCVD), plasma enhanced chemical steam deposition (PECVD), organometallic chemical vapor deposition (MOCVD) and combination thereof.The example of sputter includes but not limited to RF and DC magnetron sputtering.In some embodiments, before formation transparent conductive material layer 15, the passivation layer 10 that contains oxide or nitride forms in matrix 5.Oxycompound passivation layer 10 can be used heat growth method as thermal oxidation or deposit the formation as CVD.Nitrogenate layer deposits by CVD conventionally.In one embodiment, the passivation layer 10 that contains oxide or nitride can improve the adhesive force between matrix 5 and transparent conductive material layer 15.
The p-i-n knot of solar cell can form after transparent conductive material layer 15.More specifically, in one embodiment, N-shaped conductive semiconductor layer 20, intrinsic semiconductor layer 25 and p-type electric-conducting semiconductor layer 35 can sequentially deposit to provide p-i-n knot after forming transparent conductive material layer 15.At least one deck in N-shaped conductive semiconductor layer 20, intrinsic semiconductor layer 25 and p-type electric-conducting semiconductor layer 30 is comprised of the amorphous silicon hydride that comprises deuterium (D) and/or hydrogenated amorphous silicon alloys (being also called " material of containing hydrogenated amorphous silicon and deuterium ").In one embodiment, the material of containing hydrogenated amorphous silicon and deuterium forms as follows: the surface of the material of containing hydrogenated amorphous silicon is provided, and by the material of containing hydrogenated amorphous silicon containing annealing in deuterium atmosphere, wherein deuterium is introduced in the lattice of material of containing hydrogenated amorphous silicon.
Before using containing the processing of deuterium atmosphere, the material of containing hydrogenated amorphous silicon can comprise 20% hydrogen at the most, but does not comprise deuterium.In one embodiment, amorphous silicon hydride is used plasma enhanced chemical vapor deposition method (PECVD) deposition.PECVD is for being used electric energy to produce plasma as the chemical vapor deposition of glow discharge plasma.Plasma can be by RF (AC) frequency or DC discharge generation between two electrodes, and wherein reacting gas is contained in the space between two electrodes.As known in the art, triode electrode configuration also can be used for producing glow discharge.Electric energy is transformed into reactive group, ion, neutral atom and molecule and other by admixture of gas and is highly excited species.In the method, relate to chemical reaction, it occurs after the plasma that produces reacting gas.For example, atom and molecular fragment and deposition substrate interact to form deposited material layer.Plasma is wherein by the gas of most atoms or molecular ionization.In one embodiment, for to deposit degree of ionization with the plasma of associated materials processing be 10-4 in the electric discharge of typical electrical capacitive to the 5-10% in high density induction plasma.Under the pressure that plasma holds in the palm as 1-10 as 1-10 millitorr to several holders at several millitorrs conventionally, operate, but arc discharge and induction plasma can be at normal pressure down-firings.Plasma can provide by radio frequency electrical capacitive discharge, inductively coupled plasma (ICP), electron cyclotron resonace (ECR) and helicon.
In one embodiment, PECVD can carry out under the pressure of the depositing temperature of 50-400 ℃ and 0.1-10 holder.In another embodiment, PECVD can carry out under the pressure of the depositing temperature of 100-350 ℃ and 0.2-5 holder.
The material of containing hydrogenated amorphous silicon is deposited and is comprised at least one reacting gas that contains semi-conducting material and at least one hydrogeneous reacting gas by PECVD.In one embodiment, the reacting gas containing semi-conducting material for generation of the material of containing hydrogenated amorphous silicon comprises at least one silicon atom.For example, for the silicon components of amorphous silicon hydride is provided, the reacting gas that contains semi-conducting material can comprise SiH
4, Si
2h
6, SiH
2cl
2, SiHCl
3and SiCl
4in at least one.
The hydrogeneous reacting gas depositing by PECVD for the material that makes containing hydrogenated amorphous silicon can be hydrogen (H
2).Hydrogen atom in hydrogen is incorporated in deposition materials to form the material of containing hydrogenated amorphous silicon.Hydrogeneous reacting gas can follow at least one inert gas as the carrier gas of He, Ne, Ar, Xe, Kr or its mixture.Hydrogeneous reacting gas is followed in an embodiment of carrier gas therein, can be for pure silane is to 1:1000 containing reacting gas and the velocity ratio of the hydrogeneous reacting gas of combination and carrier gas of semi-conducting material.Hydrogeneous reacting gas is followed in another embodiment of carrier gas therein, containing the reacting gas of semi-conducting material and the velocity ratio of the hydrogeneous reacting gas of combination and carrier gas, can be 1:10-1:200.In carrier gas, hydrogen can be 1:5-5:1 with the ratio of carrier gas.In another embodiment, hydrogen can be 1:2-2:1 with the ratio of carrier gas.The flow velocity of every kind of gas can size and the goal pressure during deposition process based on Processing Room determine.According to present disclosure, point out that above flow velocity, only for illustration purpose, also can be used less and larger ratio.
In an example, the RF power for generation of plasma is 2-500mW/cm
2.In another example, RF power is 5-100mW/cm
2.In an example, the frequency of RF power is 13.56MHz.In another example, the frequency of RF power is 5-120MHz.
When the material of containing hydrogenated amorphous silicon (α-Si:H) is during for p-type electric-conducting semiconductor layer 20 and N-shaped conductive semiconductor layer 30 deposition, provide the dopant of the conduction type of material layer can in-situ deposition.Original position means to provide the dopant of the conduction type of material layer to form or introduce during deposition at material layer.
The in the situation that of p-type electric-conducting semiconductor layer 20, reacting gas can further comprise p-type dopant source.For example, diborane (B
2h
6) gas can with containing the reacting gas of semi-conducting material, hydrogeneous reacting gas and optional carrier gas, flow in Processing Room simultaneously.Carbon can be by making carbonaceous gas source as CH
4, C
2h
2, C
2h
4and C
2h
6flow and original position is incorporated in p-type layer.The in the situation that of N-shaped conductive semiconductor layer 30, reacting gas can further comprise N-shaped dopant source.For example, hydrogen phosphide (PH
3) gas or arsine (AsH
3) gas can with containing the reacting gas of semi-conducting material, hydrogeneous reacting gas and optional carrier gas, flow in Processing Room simultaneously.
After forming amorphous silicon hydride, amorphous silicon hydride can be with at least processing through a surface of hydrogenated amorphous Si containing deuterium gas.In one embodiment, the material of containing hydrogenated amorphous silicon containing annealing in deuterium atmosphere, is wherein introduced deuterium in the lattice of material of containing hydrogenated amorphous silicon (α-Si:H).In one embodiment, contain deuterium gas by 100% deuterium gas (D
2) form.In some embodiments, containing deuterium gas, can further comprise carrier gas as helium (He) gas, argon gas (Ar), Krypton (Kr), nitrogen (N
2) or its combination.For example,, when comprising carrier gas as helium (He) gas and deuterium gas (D containing deuterium gas
2) when combination, carrier gas can exist to be less than 50%, conventionally to be less than 25%, exists.
In one embodiment, amorphous silicon hydride (α-Si:H) can be greater than under the pressure of 5ATM with processing through a surface containing deuterium gas.In another embodiment, can will be greater than on the surface that is applied to amorphous silicon hydride (α-Si:H) under the pressure of 20ATM containing deuterium gas.Can will in the lip-deep temperature of amorphous silicon hydride (α-Si:H), can be 100-400 ℃ containing deuterium gas application.In one embodiment, can will in the lip-deep temperature of amorphous silicon hydride (α-Si:H), can be 150-350 ℃ containing deuterium gas application.Flow velocity containing deuterium gas can be depending on application containing the chamber size of deuterium gas.In an example, can be with the flow applications of 10-50sccm containing deuterium gas.
Owing to deuterium being incorporated in the lattice of amorphous silicon hydride containing deuterium gas application on amorphous silicon hydride, and silicon deuterium key is in the silicon position of During Annealing loss hydrogen or the silicon dangling bonds existing before annealing, i.e. unsaturated silicon position formation.Amorphous silicon hydride is used containing after deuterium gas treatment, amorphous silicon hydride is changed into the material of containing hydrogenated amorphous silicon and deuterium.
Can use the method that amorphous silicon hydride is changed into the material of containing hydrogenated amorphous silicon and deuterium to form at least one deck in p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 30 so that p-i-n knot to be provided.In one embodiment, p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 35 and N-shaped conductive semiconductor layer 30 are used three phase deposition methods to form.For example, the first stage of three phase deposition methods can deposit the phase III that the second stage of p-type electric-conducting semiconductor layer 20, three phase deposition methods can deposition intrinsic semiconductor layer 25, three phase deposition methods and can deposit N-shaped semiconductor layer 30.In another embodiment, at least one deck in p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped semiconductor layer 30 is not with the amorphous silicon hydride (α-Si:H) containing deuterium gas treatment.In one embodiment, at least one deck in p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 30 is crystalline silicon (c-Si).Crystalline silicon (c-Si) can be used chemical vapor deposition, and for example atom piezochemistry steam deposition (APCVD), low pressure chemical steam deposition (LPCVD), plasma enhanced chemical steam deposition (PECVD), organometallic chemical vapor deposit (MOCVD) and be combined to form.
After forming p-i-n knot, can in N-shaped conductive semiconductor layer 30, form back contact metallization structure 35.In one embodiment, back contact metallization structure 35 can be deposited in N-shaped conductive semiconductor layer 30 by plating, electroless-plating, physical vapor deposition, chemical vapour deposition, vacuum evaporation or its combination.
Fig. 3 has described an embodiment of the binode photovoltaic device 55 that comprises binode p-i-n solar cell, and wherein at least one layer of material of photovoltaic device 55 is comprised of the material of containing hydrogenated amorphous silicon and deuterium.By using two p-i-n to tie, when comparing with unijunction semiconductor device, the light wave scope that binode photovoltaic device 55 absorbs can improve.In one embodiment, the p-i-n knot in upper cell 60 is comprised of the material of containing hydrogenated amorphous silicon and deuterium, and bottom battery 65 is comprised of the containing hydrogenated amorphous silicon with germanium alloy and the material of deuterium.
The photovoltaic device of binode shown in Fig. 3 55 is similar to the photovoltaic device of unijunction shown in Fig. 2 50, and wherein the upper cell 60 of binode photovoltaic device 55 is similar to unijunction photovoltaic device 50 substantially.More specifically, the matrix 5a in the top battery 60 of binode photovoltaic device 55, oxycompound passivation layer 10a, transparent conductive material layer 15a, p-type electric-conducting semiconductor layer 20a, intrinsic semiconductor layer 25a and N-shaped conductive semiconductor layer 30a are similar to matrix 5, oxycompound passivation layer 10, transparent conductive material layer 15, p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and the N-shaped conductive semiconductor layer 30 of unijunction photovoltaic device 50 substantially.Therefore, the description of the matrix 5 of the photovoltaic device of unijunction shown in Fig. 2 50, oxycompound passivation layer 10, transparent conductive material layer 15, p-type electric-conducting semiconductor layer 20, intrinsic semiconductor layer 25 and N-shaped conductive semiconductor layer 30 is suitable for matrix 5a, oxycompound passivation layer 10a, transparent conductive material layer 15a, p-type electric-conducting semiconductor layer 20a, intrinsic semiconductor layer 25a and the N-shaped conductive semiconductor layer 30a of the photovoltaic device of binode shown in Fig. 3 55.
In one embodiment, the upper cell 60 of binode photovoltaic device 55 is separated with the bottom battery 65 of binode photovoltaic device 55 by tunnel layer 70.The effect of optional tunnel layer is to strengthen the p forming on the interface between top battery and bottom battery
+/ n
+the tunnelling of charge carrier on tunnel junction.In one embodiment, tunnel layer 70 can be comprised of as transparent conductive oxide transparent conductive material.In one embodiment, tunnel layer 70 can have the thickness of 5-15nm, but also can use larger and less thickness.
Still with reference to figure 3, the bottom battery 65 of binode photovoltaic device 55 comprises p-i-n knot, wherein selects p-type electric-conducting semiconductor layer 75, intrinsic semiconductor layer 80 and N-shaped conductive semiconductor layer 85 material separately to have p-type electric-conducting semiconductor layer 20a, intrinsic semiconductor layer 25a and the lower band gap of the selected material of N-shaped conductive semiconductor layer 30a of the upper cell 60 that is compared to binode photovoltaic device 55.For example, p-type electric-conducting semiconductor layer 20a when the upper cell 60 of binode photovoltaic device 55, at least one deck in intrinsic semiconductor layer 25a and N-shaped conductive semiconductor layer 30a is by also can contain the containing hydrogenated amorphous silicon of carbon and the material of deuterium and form time, the p-type electric-conducting semiconductor layer 75 that is used for the bottom battery 65 of binode photovoltaic device 55, the material of at least one deck in intrinsic semiconductor layer 80 and N-shaped conductive semiconductor layer 85 can comprise and has other alloying element as germanium and also can comprise the hydrogenated amorphous silicon material of deuterium, or can comprise the material that also can contain the nanocrystalline or microcrystal silicon of the containing hydrogenated of deuterium.The band gap that adds the material that reduces containing hydrogenated amorphous silicon and deuterium of germanium, the band gap that adds the material that improves containing hydrogenated amorphous silicon and deuterium of carbon.
When at least one deck in p-type electric-conducting semiconductor layer 75, intrinsic semiconductor layer 80 and/or the N-shaped conductive semiconductor layer 85 of the bottom of binode photovoltaic device 55 battery 65 is comprised of the material of the containing hydrogenated amorphous silicon with carbon alloy and deuterium, carbon can be introduced before deuterium gas disposal during the PECVD method that forms amorphous silicon hydride.More specifically, during deposition process, carbon containing reacting gas can flow in Processing Room between amorphous silicon hydride depositional stage.Carbon containing reacting gas can be continuously or batch (-type) ground flow in Processing Room.Carbon containing reacting gas can, for any appropriate hydrocarbon gas, include but not limited to CH
4, C
2h
2, C
2h
4and C
2h
6.The silicon source that carbonaceous gas reactant can provide with the reacting gas by containing semi-conducting material is as SiH
4, Si
2h
6, SiH
2cl
2, SiHCl
3, SiCl
4or its combination and hydrogeneous reacting gas are introduced carbonaceous gas in settling chamber simultaneously and also can be followed carrier gas as hydrogen
When the material of the containing hydrogenated amorphous silicon with carbon alloy and deuterium adulterates to provide p-type electric-conducting semiconductor layer 75 with p-type electric-conducting dopant, p-type dopant can original position be introduced during the deposition process of material that is used to form containing hydrogenated amorphous silicon.Particularly, p-type dopant can be introduced and treated by p-type dopant gas as diborane (B as boron
2h
6) in the material layer of deposition, it can be with containing the reacting gas of semi-conducting material, hydrogeneous reacting gas and/or carbon containing reacting gas simultaneously or enter in settling chamber dividually.
When the material of the containing hydrogenated amorphous silicon with carbon alloy and deuterium adulterates to provide N-shaped conductive semiconductor layer 85 with N-shaped conductivity dopant, N-shaped dopant can original position be introduced during the deposition process of material that is used to form containing hydrogenated amorphous silicon.Particularly, N-shaped dopant can be introduced by N-shaped dopant gas as hydrogen phosphide (PH as phosphorus or arsenic
3) gas or arsine (AsH
3) in the material layer of deposition, it can be with containing the reacting gas of semi-conducting material, hydrogeneous reacting gas and/or carbon containing reacting gas simultaneously or enter in settling chamber dividually.
For deuterium is introduced with the lattice of the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium containing deuterium gas treatment be similar to above about deuterium is introduced above about in the lattice of amorphous silicon hydride described in Fig. 2 containing deuterium gas treatment.
With the atomic concentration of carbon in the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium can be 1-50%.In another embodiment, with the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium in the atomic concentration of carbon can be 5-30%.With the atomic concentration of silicon in the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium can be 50-95%.In another embodiment, with the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium in the atomic concentration of silicon can be 75-85%.With the atomic concentration of deuterium in the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium for being greater than 0.001%.In another embodiment, with the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium in the atomic concentration of deuterium can be 0.001-1%.When for p-type electric-conducting semiconductor layer 75, further comprise 10 with the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium
16-10
21individual atom/cm
3p-type concentration of dopant, wherein 10
18-10
20individual atom/cm
3scope be more usually.The doping efficiency of layer in 75 ratio of total dopant atom (the activated dopants atom with) is generally 0.1-20%, but higher and lower doping efficiency is possible.Conventionally, doping efficiency reduces by improving dopant atom concentration.Equally, when for N-shaped conductive semiconductor layer 75, further comprise 10 with the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium
16-10
21individual atom/cm
3n-shaped concentration of dopant, wherein 10
18-10
20individual atom/cm
3scope be more usually.The doping efficiency of layer in 75 ratio of total dopant atom (the activated dopants atom with) is generally 0.1-20%, but higher and lower doping efficiency is possible.Conventionally, doping efficiency reduces by improving dopant atom concentration.
The band gap of the p-type electric-conducting semiconductor layer 75 of the bottom battery 65 being comprised of the material of the containing hydrogenated amorphous silicon with carbon alloy and deuterium can be 1.7-2.5eV, but also can use higher and lower band gap.Layer 75 can comprise carbon.In some embodiments, layer 75 comprises containing deuterium hydrogenated amorphous silicon carbide.The band gap of the intrinsic semiconductor layer 80 being comprised of the material of the containing hydrogenated amorphous silicon with carbon alloy and deuterium can be 1.6-1.8eV.The band gap of the N-shaped conductive semiconductor layer 85 of the bottom battery 65 being comprised of the material of the containing hydrogenated amorphous silicon with carbon alloy and deuterium can be 1.6-1.8eV.
When at least one deck in p-type electric-conducting semiconductor layer 75, intrinsic semiconductor layer 80 and/or the N-shaped conductive semiconductor layer 85 of the bottom of binode photovoltaic device 55 battery 65 is comprised of the material of the containing hydrogenated amorphous silicon with germanium alloy and deuterium, germanium can be introduced before deuterium gas disposal during the PECVD method that forms amorphous silicon hydride (α-Si:H).More specifically, during deposition process, germanic reacting gas can flow in Processing Room between the depositional stage of amorphous silicon hydride (α-Si:H).Germanic gas reactant can be continuously or batch (-type) ground flow in Processing Room.Germanic gas reactant can, for any germanium gas, include but not limited to GeH4, Ge
2h
6, GeH
2cl
2and Ge
2cl
4.The silicon source that germanic gas reactant can provide with the reacting gas by containing semi-conducting material is as SiH
4, Si
2h
6, SiH
2cl
2, SiHCl
3, SiCl
4or it combines and hydrogeneous reacting gas is introduced in settling chamber simultaneously.Germanic gas also can follow carrier gas as hydrogen.
When adulterating to provide p-type electric-conducting semiconductor layer 75 by the material of the containing hydrogenated amorphous silicon with germanium alloy and deuterium with p-type electric-conducting dopant, p-type dopant can original position be introduced during deposition process.Particularly, p-type dopant can be introduced and passed through p-type dopant gas if the material layer of diborane (B2H6) deposition is as in amorphous silicon hydride as boron, it can or enter in settling chamber dividually with the reacting gas containing semi-conducting material, hydrogeneous reacting gas and/or germanic reacting gas while.
When the material of the containing hydrogenated amorphous silicon with germanium alloy and deuterium adulterates to provide N-shaped conductive semiconductor layer 85 with N-shaped conductivity dopant, N-shaped dopant can original position be introduced between depositional stage.Particularly, N-shaped dopant can be introduced by N-shaped dopant gas as hydrogen phosphide (PH as phosphorus or arsenic
3) gas or arsine (AsH
3) material layer of deposition is as in amorphous silicon hydride, it can be with containing the reacting gas of semi-conducting material, hydrogeneous reacting gas and/or germanic reacting gas simultaneously or enter in settling chamber dividually.
For deuterium is introduced with the lattice of the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium containing deuterium gas treatment be similar to above about deuterium is introduced above about in the lattice of amorphous silicon hydride described in Fig. 2 containing deuterium gas treatment.
With the atomic concentration of germanium in the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium can be 0-100%, the scope of 1-50% is more usually.In some embodiments, with the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium in the atomic concentration of germanium can be 5-30%.In one embodiment, with the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium in the atomic concentration of silicon can be 50-95%.In another embodiment, with the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium in the atomic concentration of germanium can be 75-85%.With the atomic concentration of deuterium in the containing hydrogenated amorphous silicon of carbon alloy and the material of deuterium for being greater than 0.001%.In another embodiment, with the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium in the atomic concentration of deuterium can be 0.001-1%.When for p-type electric-conducting semiconductor layer 75, further comprise 10 with the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium
16-10
20individual atom/cm
3p-type concentration of dopant, wherein 10
18-10
20individual atom/cm
3scope be more usually.The doping efficiency of layer in 75 ratio of total dopant atom (the activated dopants atom with) is generally 0.1-20%, but higher and lower doping efficiency is possible.Conventionally, doping efficiency reduces by improving dopant atom concentration.Equally, when for N-shaped conductive semiconductor layer 85, further comprise 10 with the containing hydrogenated amorphous silicon of germanium alloy and the material of deuterium
16-10
20individual atom/cm
3n-shaped concentration of dopant, wherein 10
18-10
20individual atom/cm
3scope be more usually.The doping efficiency of layer in 75 ratio of total dopant atom (the activated dopants atom with) is generally 0.1-20%, but higher and lower doping efficiency is possible.Conventionally, doping efficiency reduces by improving dopant atom concentration.
The band gap of the p-type electric-conducting semiconductor layer 75 of the bottom battery 65 being comprised of the material of the containing hydrogenated amorphous silicon with germanium alloy and deuterium can be 0.7-1.7eV, and the scope of 1.0-1.5eV is more usually.The band gap of the intrinsic semiconductor layer 80 being comprised of the material of the containing hydrogenated amorphous silicon with germanium alloy and deuterium can be 0.7-1.7eV, and the scope of 1.0-1.5eV is more usually.The band gap of the N-shaped conductive semiconductor layer 85 of the bottom battery 65 being comprised of the material of the containing hydrogenated amorphous silicon with germanium alloy and deuterium can be 0.7-1.7eV, and the scope of 1.0-1.5eV is more usually.
Still, with reference to figure 3, binode photovoltaic device 55 further comprises back contact metallization structure 35a.The metallization structure of back contact shown in Fig. 3 35a is similar to the above back contact metallization structure 35 about unijunction photovoltaic device 50 described in Fig. 2.Therefore, the description of the metallization structure of back contact shown in Fig. 2 35 is suitable for the back contact metallization structure 35a of the photovoltaic device of binode shown in Fig. 3 55.
Fig. 4 describes an embodiment of the photovoltaic device 90 that comprises three knot p-i-n solar cells, and wherein at least one layer of material of photovoltaic device 90 is comprised of the material of containing hydrogenated amorphous silicon and deuterium.Shown in Fig. 4, three knot p-i-n solar cells are similar to the binode p-i-n solar cell shown in Fig. 3.Select material used in three knot upper cell 60a, the intermediate cell 65a of photovoltaic device 90 and the p-i-n of bottom battery 90 knot to there is different band gap, make upper cell 60a, the intermediate cell 65a of three knot photovoltaic devices 90 and the Different lightwave in bottom battery 95 absorption power generations long.
Shown in Fig. 4, three knot photovoltaic devices 90 comprise matrix 5b, oxycompound passivation layer 10b and the transparent conductive material layer 15b that is similar to matrix shown in Fig. 25, oxycompound passivation layer 10 and transparent conductive material layer 15.Therefore, the description of matrix shown in Fig. 25, oxycompound passivation layer 10 and transparent conductive material layer 15 is suitable for the 5b of matrix shown in Fig. 4, oxycompound passivation layer 10b and transparent conductive material layer 15b.
In one embodiment, the upper cell 60a of three knot photovoltaic devices 90 comprises p-type electric-conducting semiconductor layer 20b, intrinsic semiconductor layer 25b and N-shaped conductive semiconductor layer 30b, and it can be comprised of the containing hydrogenated amorphous silicon with carbon alloy and the material of deuterium separately.Be used for p-type electric-conducting semiconductor layer 20b, intrinsic semiconductor layer 25b and the containing hydrogenated amorphous silicon at least one deck and carbon alloy of N-shaped conductive semiconductor layer 30b and material of deuterium and forming method thereof as described in the material of an embodiment of the above bottom battery 65 about the photovoltaic device of binode as shown in Fig. 3 50.
The upper cell 60a of three knot photovoltaic devices 90 can be separated with the intermediate cell 65a of three knot photovoltaic devices 90 by the first tunnel junction layer 70a.The first tunnel junction layer 70a can be comprised of as transparent conductive oxide transparent conductive material.The effect of optional tunnel layer is to strengthen the p forming on the interface between top battery and intermediate cell
+/ n
+the tunnelling of charge carrier on tunnel junction.The first tunnel junction layer 70a can have the thickness of 5-15nm, but also can use thinner or thicker tunnel layer.
In one embodiment, the intermediate cell 65a of three knot photovoltaic devices 90 comprises N-shaped conductive semiconductor layer 75a, intrinsic semiconductor layer 80a and p-type electric-conducting semiconductor layer 85a, and it can be comprised of the material of containing hydrogenated amorphous silicon and deuterium separately.N-shaped conductive semiconductor layer 20, intrinsic semiconductor layer 25 and the p-type electric-conducting semiconductor layer 35 of N-shaped conductive semiconductor layer 20b, the intrinsic semiconductor layer 25b of the intermediate cell 65a of three knot photovoltaic devices 90 and the p-i-n knot that p-type electric-conducting semiconductor layer 35b is similar to the photovoltaic device of unijunction shown in Fig. 2 50.Therefore, the description of N-shaped conductive semiconductor layer 20, intrinsic semiconductor layer 25 and the p-type electric-conducting semiconductor layer 35 of the p-i-n of the photovoltaic device of unijunction shown in Fig. 2 50 knot is suitable for N-shaped conductive semiconductor layer 75a, intrinsic semiconductor layer 80a and the p-type electric-conducting semiconductor layer 85a of the intermediate cell 65a of three knot photovoltaic devices 90.
The intermediate cell 65a of three knot photovoltaic devices 95 can be separated with the bottom battery 95 of three knot photovoltaic devices 90 by the second tunnel junction layer 86.The second tunnel junction layer 86 can be comprised of as transparent conductive oxide transparent conductive material.The effect of optional tunnel layer is to strengthen the p forming on the interface between intermediate cell and bottom battery
+/ n
+the tunnelling of charge carrier on tunnel junction.The second tunnel layer 86 can have the thickness of 5-15nm, but also can use thinner or thicker tunnel layer.
Still, with reference to figure 4, in one embodiment, the bottom battery 95 of three knot photovoltaic devices 90 comprises p-type electric-conducting semiconductor layer 96, intrinsic semiconductor layer 97 and N-shaped conductive semiconductor layer 98, and it can be comprised of the containing hydrogenated amorphous silicon with germanium alloy and the material of deuterium separately.Be used for the containing hydrogenated amorphous silicon at least one deck and germanium alloy of p-type electric-conducting semiconductor layer 96, intrinsic semiconductor layer 97 and N-shaped conductive semiconductor layer 98 and material of deuterium and forming method thereof as described in the material of an embodiment of the above bottom battery 65 about the photovoltaic device of binode as shown in Fig. 3 50.
Three knot photovoltaic devices 90 further comprise back contact metallization structure 35b.The metallization structure of back contact shown in Fig. 4 35b is similar to the above back contact metallization structure 35 about unijunction photovoltaic device 50 described in Fig. 2.Therefore, the description of the metallization structure of back contact shown in Fig. 2 35 is suitable for the back contact metallization structure 35b of three knot photovoltaic devices 90 shown in Fig. 4.
Fig. 5 A has described the photovoltaic device 300 of the back contact structure 430 that has monocrystalline silicon (c-Si) absorbed layer 310 and be comprised of the material of containing hydrogenated amorphous silicon and deuterium." absorbed layer " is easily to absorb photon to produce electric charge carrier, the i.e. material in free electron or hole.Photovoltaic device between front side and absorbed layer is partly called " emission layer ", is called " emitter junction " with the knot of absorbed layer.Emission layer can be present on absorbed layer, and wherein emission layer has the conduction type with conductivity type opposite as absorbed layer.In an example, when the solar energy of photon form concentrates in battery layers, in the material of electron-hole pair in photovoltaic device, produce.Emitter junction provides required electric field so that the electronics of photogenerated and hole concentrate on respectively in the p doping and n doped side of emitter junction.For this reason, in this example, at least one deck p-type layer of photovoltaic device can provide absorbed layer and at least one deck adjacent n form layer emission layer can be provided.In other example, absorbed layer can be doping to N-shaped conductivity, and emission layer can be doping to p-type electric-conducting.At heterojunction solar battery, as shown in Fig. 5-7 in embodiment, absorbed layer 310 is starting substrate, and in meeting the p-i-n photovoltaic device of embodiment shown in Fig. 1-4, absorbed layer is sedimentary deposit, for example intrinsic semiconductor layer 25,25a, 25b.
In embodiment shown in Fig. 5 A, photovoltaic device 300 comprises projectile configuration 320.In one embodiment, projectile configuration 320 has the second conduction type, N-shaped for example, and form on as the monocrystalline silicon of p-type (c-Si) absorbed layer 310 thering is the first conduction type.
Term " monocrystalline " represents crystalline solid, wherein the lattice of whole sample be basic continous and the edge of damaged sample not substantially, substantially do not there is crystal boundary.In another embodiment, the crystal semiconductor material of absorbed layer 310 has polycrystalline structure.Contrary with monocrystalline crystal structure, the form of polycrystalline structure for forming and contain high-angle boundary, twin boundary or the semi-conducting material of the two by randomly-oriented crystallite.Polycrystalline extensively refers to have the polycrystalline material (order of magnitude of about mm to cm) of large crystal grain.Other term using is large crystal grain polycrystalline or large crystal grain polycrystalline.Term polycrystalline is often referred to little crystal grain (hundreds of nm is to hundreds of μ m).The crystal semiconductor material of absorbed layer 310 is generally material.In one embodiment, at least one in Si, Ge, SiGe, SiC and SiGeC of absorbed layer 310 forms.In yet another embodiment, absorbed layer 310 can be compound semiconductor, and for example III-IV type semiconductor is as GaAs.In an example, the crystal semiconductor material of absorbed layer 310 is comprised of single crystalline Si.In one embodiment, absorbed layer 310 has the thickness of 50nm-1mm.In another embodiment, absorbed layer 310 has the thickness of 1-500 μ m.
In one embodiment, by absorbed layer 310 use p-type dopant doping, described dopant is with 1 * 10
9-1 * 10
20individual atom/cm
3concentration exist.In another embodiment, the concentration that is present in the p-type dopant in absorbed layer 310 is 1 * 10
14-1 * 10
19individual atom/cm
3.In absorbed layer 310, the concentration of dopant of p-type dopant can be classification or uniform." evenly " means concentration of dopant is identical on the whole thickness of absorbed layer 310.For example, the absorbed layer 310 that has a Uniform Doped agent concentration can have concentration of dopant identical on the upper surface of absorbed layer 310 and bottom surface and in the upper surface of absorbed layer 10 concentration of dopant identical with absorbed layer 310 cores between bottom surface." classification " means concentration of dopant and changes on whole absorbed layer 10 thickness.In one embodiment, the band gap of absorbed layer 310 can be 0.1-7.0eV.Also absorbed layer 310 can be doping to N-shaped conductivity.
Still, with reference to figure 5A, passivation layer 305 is present in below absorbed layer 310.Passivation layer 305 is generally intrinsic.Passivation layer 305 is for by the passivating back of absorbed layer 310 and reduce electron-hole restructuring.In one embodiment, passivation layer 305 can be comprised of the material of containing hydrogenated amorphous silicon and deuterium.The material of containing hydrogenated amorphous silicon and deuterium can be similar to the above material about containing hydrogenated amorphous silicon used and deuterium in photovoltaic cell described in Fig. 2-4 50,60,60a, 65,65a, 95 p-i-n knot aspect composition.Therefore, the above composition about the material of containing hydrogenated amorphous silicon and deuterium described in Fig. 2-4 and preparation method are suitable for providing passivation layer 305 shown in Fig. 5 A.As mentioned above, in the material of containing hydrogenated amorphous silicon and deuterium, the existence of deuterium improves the stability of the material that is used for back surface field layer 305 and reduces Staebler-Wronski effect.The alloy that in some embodiments, can further comprise germanium and carbon for the containing hydrogenated amorphous silicon of back surface field layer 305 and the material of deuterium adds.
In embodiment shown in Fig. 5 A, passivation layer 305 is not pantostrat on the whole back side of absorbed layer 310.In this embodiment, local back surface district 315 is present in the back side of absorbed layer 310 and is included in the opening in passivation layer 305.Still, with reference to figure 5A, photovoltaic device 300 can further be included in the optional dielectric layer 325 on passivation layer 305.Dielectric layer 325 can be comprised of amorphous hydrogenated silicon nitride or amorphous hydrogenation silica.Dielectric layer 325 can provide to the back side of photovoltaic cell further passivation and/or reflectivity.
In one embodiment, the local back surface district 315 of formation absorbed layer 310 can start to form dielectric layer 325.Dielectric layer 325 can be used deposition process to form as CVD.The variant that is suitable for the CVD method of dielectric layer 325 includes but not limited to atmospheric pressure cvd (APCVD), low pressure chemical vapor deposition (LPCVD) and plasma-enhanced CVD (PECVD), metallorganic CVD (MOCVD) and combination thereof.Dielectric layer 325 can have the thickness of 5nm-1 μ m, and the scope of 50-300nm is more usually.
In one embodiment, can and exist the former dielectric layer 325 that selects to form at least one opening to expose at least a portion back side of absorbed layer 310 through passivation layer 305 at least.In one embodiment, formation is included on passivation layer 305 and optional dielectric layer 325 and forms pattern etching mask (patterned etch mask) (not shown) to expose at least a portion back side of absorbed layer 310 through at least one opening of passivation layer 305 and optional dielectric layer 325, and the part that is exposed to pattern etching mask and absorbed layer 310 back sides of etch passivation layer 305 and optional dielectric layer 325 optionally.
Particularly, in an example, pattern etching mask, by photoresist being applied to surface to be etched, is exposed under radiation pattern photoresist, then uses photoresist developer to make pattern development in photoresist and produces.When the patterning of photoresist completes, the part that protection photoresist covers, removes the not method for selective etching of protection zone by the region use of exposure simultaneously and removes.As used herein, the material of the first material that represents to be employed the structure of material removal methods about the term " selectivity " of material removal methods removes the speed that removes that speed is greater than another material at least.In some instances, selectivity can be for being greater than 100:1, for example 1000:1.
In one embodiment, engraving method is used the back side of absorbed layer 310 is to the expose portion that etching chemistry is optionally removed back surface field layer 305 and optional dielectric layer 325.In one embodiment, the engraving method of formation opening is anisotropic etching.Anisotropic etch method is greater than the material removal methods of the direction that is parallel to surface to be etched for the etch-rate in normal to a surface direction to be etched wherein.Anisotropic etching can comprise reactive ion etching (RIE).With regard to present disclosure in this point, other example of spendable anisotropic etching comprises ion beam milling, plasma etching or laser ablation.
After forming the opening at the back side that exposes absorbed layer 310, local back surface district 315 can be by introducing the back side of absorbed layer 310 by the dopant for local back surface district 315 by opening and forming at absorbed layer 310.For example, provide the dopant of the conduction type in local back surface district 315 can use Implantation or gas vapor to deposit mutually in introducing absorbed layer 310, be then diffused into the degree of depth of semiconductor substrate so that local back surface district 315 to be provided.Local back surface district 315 is doping to the conduction type identical with absorbed layer 310.For example, when absorbed layer 310 is p-type electric-conducting, local back surface district 315 is p-type electric-conducting." back surface field (BSF) district " as used herein is the higher doped layer at absorbed layer 310 back sides.Generation of interfaces electric field between height and doped regions, it serves as the barrier that minority carrier flows to absorbed layer 310 back sides.For example, be suitable for hindering minority carrier as the electric field of electron recombination can be by for example having 1 * 10
17-5 * 10
20individual atom/cm
3p-type concentration of dopant place, the high doped p-type back side 305 with for example have 1 * 10
14-1 * 10
18individual atom/cm
3the p-type absorbed layer 310 of p-type concentration of dopant between generation of interfaces.
After forming local back surface district 315, bottom metal contact 335Ke Yu local back surface district 315 directly contact and forms and fill through back surface field floor 305 and the optional opening of dielectric layer 325.Bottom metal contact 335 can be used physical vapor deposition (PVD) method as sputter or plating and blanket deposit (blanket deposit).Bottom metal contact 335 can be comprised of as aluminium any electric conducting material, and can have the thickness of 100nm-10 μ m, but also can use less and larger thickness.
In one embodiment, can save local back surface district 315.In this embodiment, hard contact can directly contact with the back side of absorbed layer 310 via etched opening in passivation layer 305 (and if present optional layer 325).This embodiment is commonly referred to " local back contact " structure, because hard contact 335 and local contact (via the opening) of absorbed layer 310.
Still with reference to figure 5A, on 310 of absorbed layers that projectile configuration 320 can be relative in the one side with there is back surface field layer 305 on absorbed layer 310, form.Projectile configuration 320 has the conduction type relative with the conduction type of absorbed layer 310.For example, absorbed layer 310 has in the embodiment of p-type electric-conducting therein, and projectile configuration 320 can have N-shaped conductivity.In another example, absorbed layer 310 has in the embodiment of N-shaped conductivity therein, and projectile configuration 320 has p-type electric-conducting.Projectile configuration 320 can be for being present in the material layer also directly contacting on the whole width of absorbed layer 310.Although do not describe in Fig. 5 A, in some embodiments, intrinsic semiconductor layer can be present between absorbed layer 310 and projectile configuration 320.According to present disclosure, in an example, intrinsic semiconductor layer can be comprised of the material of amorphous silicon hydride or containing hydrogenated amorphous silicon and deuterium.
Material as crystal Si in, provide the example of N-shaped dopant of the conduction type of projectile configuration 320 to include but not limited to antimony, arsenic and phosphorus.For example, in one embodiment, the conduction type that projectile configuration 320 is wherein provided as the dopant of N-shaped be 5 * 10
17-10
19individual atom/cm
3.
Upper dielectric layer 340 can be present on the upper surface of projectile configuration 320, wherein through the opening of upper dielectric layer 340, aims at emitter region 320.Upper dielectric layer 340 can be by silica, silicon nitride or combinations thereof.Can exist through the opening of upper dielectric layer 340 and can fill with front contact 345 to expose a part of projectile configuration 320 openings.Dielectric layer is as passivation layer and/or antireflecting coating.
Can will provide the dopant of the conduction type of projectile configuration 320 during the deposition process of material layer that projectile configuration 20 is provided, to use in-situ doped being incorporated in projectile configuration 320.In another embodiment, the dopant that the conduction type of projectile configuration 320 is provided can be used to Implantation and is incorporated in projectile configuration 320 after the deposition process of material layer that projectile configuration 20 is provided.
Upper dielectric layer 340 can be used CVD, for example atom piezochemistry steam deposition (APCVD), low pressure chemical steam deposition (LPCVD), plasma-reinforced chemical steam deposition (PECVD), organometallic chemical vapor deposition (MOCVD) or its combined deposition.Formation is similar to through the method for at least one opening of upper dielectric layer 340 method forming through the opening of passivation layer 305 and optional dielectric layer 325.More specifically, at least one opening through upper dielectric layer 340 is used photoetching process and method for selective etching to form.
Still, with reference to figure 5A, can form the front contact 345 of filling through at least one opening of passivation layer 305 and optional dielectric layer 325, wherein front contact 345 directly contacts with projectile configuration 320.In one embodiment, the front contact 345 of solar cell is comprised of one group of parallel narrow fingerprint line and the common wide current collection line (collector line) with the deposition that meets at right angles with respect to fingerprint line.Front contact 345 can deposit with screen printing technique.In another embodiment, front contact 345 provides by application etching or electroformed metal mould.While being formed for the metal pattern of front contact 345, metal material used can comprise that applied metal sticks with paste.Metal paste can be for any electroconductive paste be as Al sticks with paste, Ag sticks with paste or AlAg sticks with paste.While being formed for the metal pattern of front contact 345, metal material used also can be used sputter, heat/electron beam evaporation or plating and deposit.
Fig. 5 B has described an embodiment of photovoltaic device 1300, described photovoltaic device 1300 comprises (c-Si) absorbed layer (hereinafter referred to as absorbed layer 1310) that has monocrystalline silicon and the heterojunction solar battery of the projectile configuration 1320 that is comprised of the material of containing hydrogenated amorphous silicon and deuterium, wherein the overlapping projectile configuration 1320 of transparent conductive material layer 1340 and existing.Applicant proposes absorbed layer 1310 shown in Fig. 5 B and projectile configuration 1320 is similar to absorbed layer 1310 shown in Fig. 5 A and projectile configuration 1320.Therefore, about the absorbed layer 310 of Fig. 5 A and the description of projectile configuration 320, be applicable to absorbed layer 1310 and projectile configuration 1320 described in Fig. 5 B.
In one embodiment, projectile configuration 1320 is comprised of amorphous silicon hydride, and it is relative with the conductivity of absorbed layer 1310 that wherein amorphous silicon hydride is doping to conductivity.For example, when absorbed layer 1310 is doping to N-shaped conductivity, projectile configuration 1320 is doping to p-type electric-conducting.In another example, when absorbed layer 1310 is doping to p-type electric-conducting, projectile configuration 1320 is doping to N-shaped conductivity.
In embodiment shown in Fig. 5 B, intrinsic semiconductor layer 1350 is depicted between absorbed layer 1310 and projectile configuration 1320.Intrinsic semiconductor layer 1350 can be the material of containing hydrogenated amorphous silicon and deuterium, and it can be deposited on absorbed layer 1310 before forming projectile configuration 1320.In some embodiments, at least one deck in projectile configuration 1320 and intrinsic semiconductor layer 1350 is comprised of the material of containing hydrogenated amorphous silicon and deuterium.As mentioned above, in the material of containing hydrogenated amorphous silicon and deuterium, the existence of deuterium improves the stability for the material of projectile configuration 1320 and/or intrinsic semiconductor layer 1350.Be used for projectile configuration 1320 and/or the containing hydrogenated amorphous silicon of intrinsic semiconductor layer 1350 and the material of deuterium and aspect composition, be similar to the above knot of the p-i-n about photovoltaic cell described in Fig. 2-4 50,55,90 containing hydrogenated amorphous silicon used and the material of deuterium.Therefore, the above composition about the material of containing hydrogenated amorphous silicon and deuterium described in Fig. 2-4 and preparation method are suitable for providing projectile configuration 1320 and/or intrinsic semiconductor layer 1350 described in Fig. 5 B.
In one embodiment, the transparent conductive material layer 1340 forming in projectile configuration 1320 by photovoltaic device structure, there is electronics and hole photogenerated time electromagnetic radiation within the scope of be that transparent material forms.For example, transparent conductive material layer 1340 can be by transparent conductive oxide (TCO) as the tin oxide (SnO of fluorine doping
2: F), zinc oxide (ZnO:Al) or the tin indium oxide of aluminium doping form.Transparent conductive material layer 1340 thickness separately can be 100nm-3 μ m, but also can use less and larger thickness.
Still, with reference to figure 5B, passivation layer 1305 is present in below absorbed layer 1310.Passivation layer 1305 is generally intrinsic.Passivation layer 1305 is for by the passivating back of absorbed layer 1310 and reduce electron-hole restructuring.In one embodiment, passivation layer 1305 can be comprised of the material of containing hydrogenated amorphous silicon and deuterium.The material of containing hydrogenated amorphous silicon and deuterium can be similar to the above material about containing hydrogenated amorphous silicon used and deuterium in photovoltaic cell described in Fig. 2-4 50,60,60a, 65,65a, 95 p-i-n knot aspect composition.Therefore, the above composition about the material of containing hydrogenated amorphous silicon and deuterium described in Fig. 2-4 and preparation method are suitable for providing passivation layer 1305 shown in Fig. 5 B.As mentioned above, in the material of containing hydrogenated amorphous silicon and deuterium, the existence of deuterium improves the stability of the material that is used for back surface field layer 1305 and reduces Staebler-Wronski effect.In some embodiments, the alloy that the containing hydrogenated amorphous silicon providing for back surface field layer 1305 and the material of deuterium can further comprise germanium and carbon adds.
In embodiment shown in Fig. 5 B, passivation layer 1305 is not pantostrat on the whole back side of absorbed layer 1310.In this embodiment, local back surface district 1315 is present in the back side of absorbed layer 1310 and is included in the opening in passivation layer 1305.Still, with reference to figure 5B, photovoltaic device 1300 can further be included in the optional dielectric layer 1325 on passivation layer 1305.Dielectric layer 1325 can be comprised of amorphous hydrogenated silicon nitride or amorphous hydrogenation silica.Dielectric layer 1325 can provide to the back side of photovoltaic cell further passivation and/or reflectivity.
In one embodiment, the local back surface district 1315 of formation absorbed layer 1310 can start to form dielectric layer 1325.Dielectric layer 1325 can be used deposition process to form as CVD.Dielectric layer 1325 can have the thickness of 5nm-1 μ m, and the scope of 50-300nm is more usually.In one embodiment, can and there is former at least a portion back side of selecting dielectric layer 1325 to form to expose absorbed layer 1310 through passivation layer 1305 at least at least one opening.In one embodiment, formation is included on passivation layer 1305 and optional dielectric layer 1325 and forms pattern etching mask (not shown) to expose at least a portion back side of absorbed layer 1310 through at least one opening of passivation layer 1305 and optional dielectric layer 1325, and the part that is exposed to pattern etching mask and absorbed layer 1310 back sides of etch passivation layer 1305 and optional dielectric layer 1325 optionally.
In one embodiment, engraving method is used the back side of absorbed layer 1310 is to the expose portion that etching chemistry is optionally removed back surface field layer 1305 and optional dielectric layer 1325.In one embodiment, the engraving method of formation opening is that anisotropic etching is as reactive ion etching (RIE), ion beam milling, plasma etching, laser ablation or its combination.After forming the opening at the back side that exposes absorbed layer 1310, local back surface district 1315 can be by introducing the back side of absorbed layer 1310 by the dopant for local back surface district 1315 by opening and forming at absorbed layer 1310.For example, provide the dopant of the conduction type in local back surface district 1315 can use Implantation or gas vapor to deposit mutually and introduce in absorbed layer 1310, be then diffused into the degree of depth of semiconductor substrate so that local back surface district 1315 to be provided.Local back surface district 1315 is doping to the conduction type identical with absorbed layer 1310.For example, when absorbed layer 1310 is p-type electric-conducting, local back surface district 1315 is p-type electric-conducting.Generation of interfaces electric field between height and doped regions, it serves as the barrier that minority carrier flows to absorbed layer 1310 back sides.For example, be suitable for hindering minority carrier as the electric field of electron recombination can be by for example having 1 * 10
17-5 * 10
20individual atom/cm
3p-type concentration of dopant place, the high doped p-type back side 1305 with for example have 1 * 10
14-1 * 10
18individual atom/cm
3the p-type absorbed layer 310 of p-type concentration of dopant between generation of interfaces.
After forming local back surface district 1315, bottom metal contact 1335 Ke Yu local back surface districts 1315 directly contacts and form and fill through back surface field floor 1305 and the optional opening of dielectric layer 1325.Bottom metal contact 1335 can be used physical vapor deposition (PVD) method as sputter or plating and blanket deposit.Bottom metal contact 1335 can be comprised of as aluminium any electric conducting material, and can have the thickness of 100nm-10 μ m, but also can use less and larger thickness.
In one embodiment, can save local back surface district 1315.In this embodiment, hard contact can directly contact with the back side of absorbed layer 1310 via etched opening in passivation layer 1305 (and if present optional layer 1325).This embodiment is commonly referred to " local back contact " structure, because hard contact 1335 and local contact (via the opening) of absorbed layer 1310.
Fig. 6 has described to have the embodiment of photovoltaic device 300a of the heterojunction solar battery of front and rear heterojunction contacts.Applicant proposes the 310a of absorbed layer shown in Fig. 6 and projectile configuration 320a is similar to absorbed layer 310 shown in Fig. 5 A and projectile configuration 320.Therefore, the description about absorbed layer 310 described in Fig. 5 A and projectile configuration 320 is applicable to the 310a of absorbed layer shown in Fig. 6 and projectile configuration 320a.In one embodiment, projectile configuration 320a is comprised of amorphous silicon hydride, and it is relative with the conductivity of absorbed layer 310a that wherein amorphous silicon hydride is doping to conductivity.For example, when absorbed layer 310a is doping to N-shaped conductivity, projectile configuration 320a is doping to p-type electric-conducting.In another example, when absorbed layer 310a is doping to p-type electric-conducting, projectile configuration 320a is doping to N-shaped conductivity.In some embodiments, projectile configuration 320a is comprised of the material of containing hydrogenated amorphous silicon and deuterium.As mentioned above, in the material of containing hydrogenated amorphous silicon and deuterium, the existence of deuterium improves the stability with respect to variations in temperature and/or illumination for the material of projectile configuration 320, therefore reduces the passivation that provides by contact before or after containing hydrogenated amorphous Si and/or electric field with respect to the unsteadiness (Staebler-Wronski effect) of variations in temperature and/or illumination.The 340a of upper dielectric layer shown in Fig. 6 and front contact 345a are similar to upper dielectric layer 340 shown in Fig. 5 A and front contact 345.
In embodiment shown in Fig. 6, positive intrinsic semiconductor layer 505 is depicted between absorbed layer 310a and projectile configuration 320a.Positive intrinsic semiconductor layer 505 can be the material of containing hydrogenated amorphous silicon and deuterium, and it can be deposited on absorbed layer 310a before forming projectile configuration 320a.Back side intrinsic semiconductor layer 510 can form on the surface relative with there is positive intrinsic semiconductor layer 505 of absorbed layer 310a.Back side intrinsic semiconductor layer 510 also can be comprised of the material of amorphous silicon hydride and/or containing hydrogenated amorphous silicon and deuterium.In some embodiments, the material of amorphous silicon hydride and/or containing hydrogenated amorphous silicon and deuterium can further comprise germanium and the carbon of classification or uniform concentration.
Be used for the material that positive intrinsic semiconductor layer 505 and the containing hydrogenated amorphous silicon of back side intrinsic semiconductor layer 510 and the material of deuterium can be similar to the above knot containing hydrogenated amorphous silicon used of the p-i-n about photovoltaic cell described in Fig. 2-4 50,55,90 and deuterium aspect composition.Therefore, the above composition about the material of containing hydrogenated amorphous silicon and deuterium described in Fig. 2-4 and preparation method are suitable for providing positive intrinsic semiconductor layer 505 and back side intrinsic semiconductor layer 510 shown in Fig. 6.As mentioned above, in the material of containing hydrogenated amorphous silicon and deuterium, the existence of deuterium improves the stability with respect to variations in temperature and/or illumination for the material of positive intrinsic semiconductor layer 505 and back side intrinsic semiconductor layer 510, therefore reduces the passivation that provides by contact before or after containing hydrogenated amorphous Si and/or electric field with respect to the unsteadiness (Staebler-Wronski effect) of variations in temperature and/or illumination.
Still, with reference to figure 6, doped hydrogenated amorphous silicon layer 515 forms in intrinsic semiconductor layer 510 overleaf.Doped hydrogenated amorphous silicon layer 515 can be comprised of the material of containing hydrogenated amorphous silicon and deuterium and can be doping to the conductivity identical with absorbed layer 310a.For example, when absorbed layer 310a is doping to N-shaped conductivity, doped hydrogenated amorphous silicon layer 515 is doping to N-shaped conductivity, when absorbed layer 310a is doping to p-type electric-conducting, doped hydrogenated amorphous silicon layer 515 is doping to p-type electric-conducting.Be suitable for the composition of the containing hydrogenated amorphous silicon of doped hydrogenated amorphous silicon layer 515 and the material of deuterium and preparation method as above about as described in Fig. 2-4.
The back side transparent conductive material layer 520 that described in Fig. 6, photovoltaic device 300a can further be included in the upper front transparent conductive material layer 525 forming of projectile configuration 320a and form on doped hydrogenated amorphous silicon layer 515.Within the scope of electromagnetic radiation when front and back transparent conductive material layer 525,520 is generally comprised within the photogenerated that electronics and hole occur in photovoltaic device structure, it is transparent material.For example, front and back transparent conductive material layer 525,520 separately can be by transparent conductive oxide (TCO) as the tin oxide (SnO of fluorine doping
2: F), zinc oxide (ZnO:Al) or the tin indium oxide of aluminium doping form.Front and back transparent conductive material layer 525,520 thickness separately can be 100nm-3 μ m, but also can use less and larger thickness.Conventionally, when absorbed layer 310a is monocrystalline or polycrystalline Si, the thickness of front and back transparent conductive material is 70-100nm so that from positive light reflection minimized and make to maximize from the light reflection at the back side of absorbed layer 310a.
Fig. 7 described to comprise there are two emitter Facad structure 320b, 330 and the photovoltaic device 300b of the solar cell device of heterojunction structure.The 310b of absorbed layer shown in Fig. 7, back side intrinsic semiconductor layer 510a, doped hydrogenated amorphous silicon layer 515a, back side transparent conductive material layer 520a and back contact 530a are similar to the 310a of absorbed layer shown in Fig. 6, back side intrinsic semiconductor layer 510, doped hydrogenated amorphous silicon layer 515, back side transparent conductive material layer 520 and back contact 530.Therefore, described in Fig. 6, the description of absorbed layer 310a, back side intrinsic semiconductor layer 510, doped hydrogenated amorphous silicon layer 515, back side transparent conductive material layer 520 and back contact 530 is suitable for absorbed layer 310b, back side intrinsic semiconductor layer 510a described in Fig. 7, doped hydrogenated amorphous silicon layer 515a, back side transparent conductive material layer 520a and back contact 530a.
Two projectile configuration 320b, 330 can existing on the relative face of the side of back side intrinsic semiconductor layer 510a and forming with absorbed layer 310b at absorbed layer 310b.Two projectile configuration 320b, 330 have the conduction type relative with the conduction type of absorbed layer 310b.For example, absorbed layer 310b has in the embodiment of p-type electric-conducting therein, and two projectile configuration 320b, 330 can have N-shaped conductivity.In another example, absorbed layer 310b has in the embodiment of N-shaped conductivity therein, and two projectile configuration 320b, 330 can have p-type electric-conducting.
Two projectile configuration 320b, 330 can comprise the first emitter region 320b and the second emitter region 330.The first projectile configuration 320b can be for being present in the material layer also directly contacting on the whole width of absorbed layer absorbed layer 310b.The second emitter region 330 can have the conductivity identical with the first projectile configuration 320b, wherein represents that the concentration of dopant of the conduction type of material is greater than in the first emitter region 320b in the second emitter region 330.In one embodiment, the first emitter region 320b is the pantostrat being present on the whole width of absorbed layer 310b, and the second emitter region 330 is comprised of the island of discontinuous material, places the front contact 345a that the island of described discontinuous material forms subsequently with contact.
The first and second emitter region 320b, 330 can be comprised of as Si, Ge, SiGe, SiC, SiGeC and combination thereof crystalline semiconductor layer separately.In another embodiment, the first and second emitter region 320b, 330 also can be comprised of as GaAs III-IV type semiconductor compound semiconductor.In material, provide the example of N-shaped dopant of the conduction type of the first emitter region 320b and the second emitter region 330 to include but not limited to antimony, arsenic and phosphorus.Upper dielectric layer 340a can be present on two projectile configuration 320b, 330 upper surface, wherein through the opening of upper dielectric layer 340a, aims at the second emitter region 330.Upper dielectric layer 340a can be by silica, silicon nitride or combinations thereof.Opening can exist through the upper dielectric layer 340a corresponding to projectile configuration 320b, the second emitter region 330 of 330.Opening can be filled with the front contact 345a forming subsequently.
In one embodiment, forming two projectile configuration 320b, 330 can start to deposit the first emitter region 320b on absorbed layer 310b.When the first emitter region 320b is comprised of crystal semiconductor material, crystal semiconductor material can be used the CVD method deposition that is selected from atom piezochemistry steam deposition (APCVD), low pressure chemical steam deposition (LPCVD), plasma-reinforced chemical steam deposition (PECVD), organometallic chemical vapor deposition (MOCVD) and combination thereof.It can be 2nm-2 μ m that the thickness of the layer of the first emitter region 320b is provided.In another embodiment, providing the thickness of the layer of the first emitter region 320b can be 3-500nm.
Provide the dopant of the conduction type of the first emitter region 320b can during the deposition process of material layer that the first emitter region 320b is provided, use in-situ doped being incorporated in the first emitter region 320b.In another embodiment, can after the deposition process of material layer that the first emitter region 320 is provided, use Implantation to be incorporated in the first emitter region 320 dopant that the conduction type of the first emitter region 320 is provided.
Use upper dielectric layer 340a to implant in the first emitter region 320b as implanting mask the dopant that the conduction type of the second emitter region 330 is provided.For example, in one embodiment, dielectric layer 340a forms on the first emitter region 320b, and patterning and the opening that is etched with the part that exposure the first emitter region 320b is provided, and is implanted to provide the second emitter region 330.Upper dielectric layer 340a can be used CVD as atom piezochemistry steam deposition (APCVD), low pressure chemical steam deposition (LPCVD), plasma-reinforced chemical steam deposition (PECVD), organometallic chemical vapor deposition (MOCVD) or its combined deposition.
In one embodiment, at least one opening through upper dielectric layer 340 is used photoetching process and method for selective etching to form.After form exposing the opening of the first emitter region 320b, can in the first emitter region 320b, form by the dopant for the second emitter region 330 being introduced by the opening of upper dielectric layer 340a in the expose portion of the first emitter region 320b the second emitter region 330.For example, can use Implantation or gas vapor to deposit mutually the dopant that the conduction type of the second emitter region 330 is provided introduces in the first emitter region 320b.Concentration of dopant in the second emitter region 330 is greater than the concentration of dopant in the first emitter region 320b.For example, therein the first projectile configuration 320b and the second projectile configuration 330 are doping in an embodiment of N-shaped conductivity, the concentration of dopant in the first projectile configuration 320b can be 5 * 10
17-1 * 10
19individual atom/cm
3, the concentration of dopant in the second projectile configuration 330 can be 1 * 10
18-5 * 10
19individual atom/cm
3.
After forming the second emitter region 330, front contact 345 directly contacts formation with the second emitter region 330, fills the opening in upper dielectric layer 340a.In one embodiment, the front contact 345 of solar cell is comprised of one group of parallel narrow fingerprint line and the common wide current collection line with the deposition that meets at right angles with respect to fingerprint line.Front contact 345 can deposit with screen printing technique.In another embodiment, front contact 345 provides by application etching or electroformed metal mould.While being formed for the metal pattern of front contact 345, metal material used can comprise that applied metal sticks with paste.Metal paste can be for any electroconductive paste be as Al sticks with paste, Ag sticks with paste or AlAg sticks with paste.While being formed for the metal pattern of front contact 345, metal material used also can be used sputter, heat/electron beam evaporation or plating and deposit.
In another embodiment, optional positive intrinsic semiconductor layer (not describing) is depicted between absorbed layer 310b and the first emitter region 320b.Positive intrinsic semiconductor layer can be the material of containing hydrogenated amorphous silicon and deuterium, and it can be deposited on absorbed layer 310b before forming the first emitter region 320b.
Fig. 8 has described an embodiment of tandem photovoltaic device 400, described tandem photovoltaic device 400 comprises the upper cell 415 that the material by containing hydrogenated amorphous silicon and deuterium forms, and the bottom battery 425 being comprised of as crystalline silicon (c-Si) crystal semiconductor material.Upper cell 415 can comprise p-type electric-conducting semiconductor layer, intrinsic layer and N-shaped conductive semiconductor layer.The upper cell 415 of tandem photovoltaic device 400 is similar to the p-i-n knot of the photovoltaic device of unijunction shown in Fig. 2 50, and comprises p-type electric-conducting semiconductor layer, intrinsic layer and N-shaped conductive semiconductor layer.Therefore, composition and the formation method for p-type electric-conducting semiconductor layer 20, intrinsic layer 25 and the N-shaped conductive semiconductor layer 30 of unijunction photovoltaic device 400 described in Fig. 2 is suitable for upper cell shown in Fig. 8 415.At least one deck of the p-type electric-conducting semiconductor layer of upper cell 415, intrinsic layer and N-shaped conductive semiconductor layer can be comprised of the material of containing hydrogenated amorphous silicon and deuterium, wherein optionally adds carbon and germanium.Tandem photovoltaic device 400 can further comprise and is similar to the matrix 5 of the photovoltaic device of unijunction shown in Fig. 2 50 and the matrix 405 of transparent conductive material layer 15 and transparent conductive material layer 410.
In one embodiment, centre tunnel layer 420 can be present between upper cell 415 and bottom battery 425.The effect of optional tunnel layer is to strengthen the p forming on the interface between top battery and bottom battery
+/ n
+the tunnelling of charge carrier on tunnel junction.Tunnel layer 420 can be comprised of as transparent conductive oxide transparent conductive material.Tunnel layer 420 can have the thickness of 5-15nm, but also can use thinner or thicker tunnel layer.
Tandem photovoltaic device 400 can further comprise back contact structure 430, and it is similar to the above back contact metallization structure 35 about unijunction photovoltaic device 50 described in Fig. 2.
The material of containing hydrogenated amorphous silicon and deuterium has than the band gap as higher in 1.1eV of crystalline silicon as 1.7eV.Therefore, the material of containing hydrogenated amorphous silicon and deuterium absorbs the visible part of solar spectrum more strongly than dark heat.Therefore, the top battery 415 of the tandem photovoltaic device 400 being comprised of the material of containing hydrogenated amorphous silicon and deuterium absorbs visible rays, and the bottom battery 425 of the tandem photovoltaic device 400 being comprised of crystalline silicon absorbs the dark heat of bottom battery 425.
Provide following examples further to set forth some embodiments of present disclosure and prove more consequent advantages.More specifically, following examples proof the inventive method is improved amorphous silicon hydride passivation with respect to the effect of the stability of thermal cycle and illumination.Present disclosure is not intended to be limited to disclosed specific embodiment.
Embodiment 1: at the temperature higher than room temperature, passivation is deteriorated
Deuterium annealing at the temperature of the pressure of about 20atm and 200 ℃ and 350 ℃ is applied on N-shaped crystalline silicon (c-Si) sheet 200 that 300 μ m are thick, and as shown in Figure 9, the both sides of crystal silicon chip 200 all have the amorphous silicon hydride passivation layer 100 that 120nm is thick.With the sample of deuterium annealing in process hereinafter referred to as " deuterium annealing sample ".Control sample is also provided, wherein routine is formed to gas annealing and be applied on N-shaped crystal silicon chip that 300 μ m are thick, N-shaped crystalline silicon (c-Si) sheet both sides all have the amorphous silicon hydride passivation layer that 120nm is thick.Form gas annealing and comprise 20:1N
2/ H
2gaseous environment.The control sample of processing with formation gas annealing is hereinafter referred to as " forming gas annealing sample ".Then by deuterium annealing sample with form gas annealing sample measurement electrical property.
Figure 10 is for describing for deuterium annealing sample and forming gas annealing sample, and the efficient carrier life-span of measuring in N-shaped crystalline silicon (c-Si) sheet is with respect to the line chart of annealing temperature.The line being represented by reference number 110 is the effective minority carrier lifetime by deuterium annealing sample measurement, and the line being represented by reference number 120 is served as reasons and formed effective minority carrier lifetime of gas annealing sample measurement.Figure 10 is illustrated in annealing later immediately by deuterium and the efficient carrier life-span that forms gas annealing sample measurement.Figure 10 sets forth in deuterium gas annealing sample 110 after annealing passivation quality immediately and uses the passivation quality in the formation gas annealing sample 120 of uniform temp and pressure initiation suitable.
Then by sample, another annealing steps that deuterium annealing sample and formation gas annealing sample are used at 100 ℃ processes to simulate the passivation quality deterioration along with the time.By deuterium gas sample and formation gas annealing sample are annealed at 100 ℃, the deteriorated and deuterium gas sample of passivation quality is compared acceleration with the passivation quality deterioration of formation gas annealing sample at room temperature 20-25 ℃.Figure 11 is for deuterium annealing sample and forms gas annealing sample, effective minority carrier lifetime (millisecond) of measuring in N-shaped crystalline silicon (c-Si) sheet with respect to the annealing time at 100 ℃ (minute) figure.After the annealing of deuterium gas or formation gas annealing, the time of annealing at 100 ℃ is called the relaxation time.
The line being represented by the reference number 130a effective minority carrier lifetime that the deuterium sample with structure shown in Figure 11 (" 200 ℃ of annealing samples of deuterium ") of annealing is measured of serving as reasons at 200 ℃, the line being represented by the reference number 130b effective minority carrier lifetime that the deuterium sample with structure shown in Fig. 9 (" 350 ℃ of annealing samples of deuterium ") of annealing at 350 ℃ is measured of serving as reasons.The effective minority carrier lifetime that gas sample (" forming 200 ℃ of annealing samples of gas ") is measured that forms with structure shown in Figure 11 that the line being represented by reference number 140a is served as reasons and annealed at 200 ℃, the effective minority carrier lifetime that forms gas sample (" forming 350 ℃ of annealing samples of gas ") measurement with structure shown in Figure 11 that the line being represented by reference number 140b is served as reasons and annealed at 350 ℃.
As shown in line 130a, 130b in Figure 11,140a, 140b, effective minority carrier lifetime for 200 ℃ of annealing samples of deuterium and 350 ℃ of annealing samples of deuterium, compare with effective minority carrier lifetime of 200 ℃ of annealing samples of formation gas and 350 ℃ of annealing samples of formation gas, 350 ℃ of annealing samples of 200 ℃ of annealing samples of deuterium and deuterium are in the relaxation time, and at 100 ℃, the passivation quality deterioration after annealing is lower.Lower passivation quality deterioration means along with the relaxation time increases, and deuterium annealing sample has the larger efficient carrier life-span of formation gas annealing sample of processing than at the same temperature.
Embodiment 2: the passivation in response to illumination is deteriorated
Deuterium annealing at the temperature of the pressure of about 20atm and 200 ℃ is applied on N-shaped crystalline silicon (c-Si) sheet that 300 μ m are thick, and as shown in Figure 7, the both sides of N-shaped crystal silicon chip all have the amorphous silicon hydride passivation layer that 120nm is thick.With the sample of deuterium annealing in process hereinafter referred to as " deuterium annealing sample ".Control sample is also provided, wherein routine at 200 ℃ is formed to gas annealing and be applied on N-shaped crystal silicon chip that 300 μ m are thick, the both sides of N-shaped crystal silicon chip all have the amorphous silicon hydride passivation layer that 120nm is thick.Form gas annealing and comprise 20:1N
2/ H
2gaseous environment.The control sample of processing with formation gas annealing is hereinafter referred to as " forming gas annealing sample ".
Then having~illumination of luminous intensity on the 5th under as the function of time by deuterium annealing sample with form effective minority carrier lifetime of gas annealing sample measurement N-shaped crystal silicon chip.By sample, be that deuterium annealing sample and formation gas annealing sample are arranged on thermoreceptor, described thermoreceptor is connected with the radiator for liquid cools, and the temperature of monitoring sample to be to guarantee sample, i.e. deuterium annealing sample and form gas annealing sample and remaining between illumination period under room temperature (20-25 ℃).The result of recording light photograph.
Figure 12 is for the formation gas annealing sample of annealing and deuterium gas annealing sample at 200 ℃ in advance separately, effective minority carrier lifetime (millisecond) of measuring in N-shaped crystalline silicon (c-Si) with respect to the time under the luminous intensity of~5 daylight under room temperature (20-25 ℃) (minute) line chart.Serve as reasons at 200 ℃ effective minority carrier lifetime of deuterium gas annealing sample measurement of annealing of the line being represented by reference number 150.The effective minority carrier lifetime that forms gas annealing sample measurement that the line being represented by reference number 160 is served as reasons and annealed at 200 ℃.Minority carrier lifetime under illumination in N-shaped crystal silicon chip deteriorated lower than forming gas annealing sample for deuterium gas annealing sample, represents more stable amorphous silicon hydride passivation.
Embodiment 3: secondary ion mass spectrometry
Deuterium annealing at the temperature of the pressure of about 20atm and 200 ℃ and 350 ℃ is applied on N-shaped crystalline silicon (c-Si) sheet that 300 μ m are thick, and as shown in Figure 9, the both sides of c-Si sheet all have the amorphous silicon hydride passivation layer that 120nm is thick.At 200 ℃, use the sample of deuterium annealing in process hereinafter referred to as " 200 ℃ of annealing samples of deuterium ".At 350 ℃, use the sample of deuterium annealing in process hereinafter referred to as " 350 ℃ of annealing samples of deuterium ".Then by deuterium annealing sample with form gas annealing sample measurement SIMS depth curve.
Figure 13 (a) is the depth curve by 200 ℃ of annealing sample measurements of deuterium, and Figure 13 (b) is the depth curve by 350 ℃ of annealing sample measurements of deuterium.Under 200 ℃ (Figure 13 (a)) and 350 ℃ (Figure 13 (b)), with deuterium (the D)/hydrogen (H) in the hydrogenated amorphous silicon film of high pressure deuterium gas annealing in process, than (D/H ratio), be respectively 0.019% and 1.36%.Point out 0.019% D/H ratio be equivalent to~10
17cm
-3deuterium density (in supposition α-Si:H~hydrogen (H)/silicon (Si) of 10% than and for Si 5 * 10
22cm
-3atomic density), the order of magnitude is higher than the dangling bonds density in device quality amorphous silicon hydride.Due at 200 ℃ and 350 ℃ by the useful life of the sample of deuterium gas annealing in process under heat balance (after lax) equate, as painted in Figure 11, by deuterium gas at 350 ℃ annealing be incorporated to excessive deuterium in amorphous silicon hydride do not contribute amorphous silicon hydride in the heat balance of weak bond and dangling bonds.
Although show especially and described present disclosure about its preferred embodiment, those skilled in the art are to be understood that the spirit and scope that can not depart from present disclosure make other variation of aforementioned and form and details.Therefore, present disclosure be intended to be not limited to exact form and the details describing and set forth, but belong in the scope of appended claims.
Claims (21)
1. form the method for photovoltaic device, it comprises:
The material with surperficial containing hydrogenated amorphous silicon is provided; With
The material of containing hydrogenated amorphous silicon containing annealing in deuterium atmosphere, is wherein introduced deuterium in the lattice of material of containing hydrogenated amorphous silicon.
2. according to the process of claim 1 wherein that the materials'use plasma-reinforced chemical vapor deposition method of containing hydrogenated amorphous silicon deposits.
3. according to the method for claim 2, wherein the precursor gases of plasma-reinforced chemical vapor deposition method comprises containing silane gas and hydrogen-containing gas.
4. according to the method for claim 3, wherein capacitive discharge is by being greater than 2mW/cm
2rF power density provide.
5. according to the method for claim 4, wherein plasma-reinforced chemical vapor deposition method comprises the temperature of 100-400 ℃ and the pressure of 20 millitorr to 10 holders.
6. according to the process of claim 1 wherein that the material of containing hydrogenated amorphous silicon is selected from amorphous silicon hydride, hydrogenated amorphous SiGe, hydrogenated amorphous silicon carbide and combination thereof.
According to the process of claim 1 wherein containing deuterium atmosphere comprise 1-500sccm containing deuterium air-flow.
8. according to the method for claim 7, wherein containing deuterium air-flow, comprise 100% deuterium.
9. according to the method for claim 7, wherein containing deuterium gas, comprise deuterium and at least one is selected from the combination of gases of helium, argon gas, Krypton, nitrogen and combination thereof.
10. according to the method for claim 7, wherein the material of containing hydrogenated amorphous silicon comprises the temperature of 100-400 ℃ in the annealing containing in deuterium atmosphere.
11. according to the method for claim 9, and wherein the surface of the material of containing hydrogenated amorphous silicon comprises and is greater than 5 atmospheric pressure in the annealing containing in deuterium atmosphere.
12. according to the process of claim 1 wherein that deuterium in the lattice of the material of introducing containing hydrogenated amorphous silicon provides the material of the containing hydrogenated amorphous silicon of processing through deuterium, and it comprises and is greater than 90 atom % silicon, is greater than 5 atom % hydrogen and is greater than 0.001 atom % deuterium.
13. according to the method for claim 12, and the material of the containing hydrogenated amorphous silicon that wherein comprises deuterium in the lattice of the material of containing hydrogenated amorphous silicon is the intrinsic-OR doped layer of p-i-n photovoltaic cell.
14. according to the method for claim 12, the contact layer that the material of the containing hydrogenated amorphous silicon that wherein comprises deuterium in the lattice of the material of containing hydrogenated amorphous silicon is heterojunction solar battery.
15. according to the passivation layer that the process of claim 1 wherein that the material of the containing hydrogenated amorphous silicon that comprises deuterium in the lattice of the material of containing hydrogenated amorphous silicon is photovoltaic device.
16. photovoltaic devices, it comprises:
The material of containing hydrogenated amorphous silicon and deuterium, it comprises and is greater than 90 atom % silicon, is greater than 5 atom % hydrogen and is greater than 0.001 atom % deuterium, wherein deuterium and unsettled silicon key bonding with containing the hydrogenated amorphous silicon layer of deuterium, do not compare the stability of the material that improves containing hydrogenated amorphous silicon and deuterium.
17. according to the photovoltaic device of claim 15, and wherein deuterium is present in the material of containing hydrogenated amorphous silicon and deuterium with 5 atom %.
18. according to the photovoltaic device of claim 15, and wherein the material of containing hydrogenated amorphous silicon and deuterium further comprises at least one in germanium and carbon.
19. according to the photovoltaic device of claim 15, and wherein the material of containing hydrogenated amorphous silicon and deuterium is the intrinsic-OR doped layer of p-i-n photovoltaic cell.
20. according to the photovoltaic device of claim 15, and wherein the material of containing hydrogenated amorphous silicon and deuterium is present in heterojunction solar battery.
21. according to the photovoltaic device of claim 15, the passivation layer that wherein material of containing hydrogenated amorphous silicon and deuterium is photovoltaic device.
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US13/188,214 US8778448B2 (en) | 2011-07-21 | 2011-07-21 | Method of stabilizing hydrogenated amorphous silicon and amorphous hydrogenated silicon alloys |
PCT/US2012/028686 WO2013012454A1 (en) | 2011-07-21 | 2012-03-12 | Method of stabilizing hydrogenated amorphous silicon and amorphous hydrogenated silicon alloys |
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US9812599B2 (en) | 2017-11-07 |
US20150340532A1 (en) | 2015-11-26 |
US20130019944A1 (en) | 2013-01-24 |
US8778448B2 (en) | 2014-07-15 |
WO2013012454A1 (en) | 2013-01-24 |
DE112012003057T5 (en) | 2014-06-12 |
US9099585B2 (en) | 2015-08-04 |
US20130019945A1 (en) | 2013-01-24 |
CN103718276B (en) | 2016-05-18 |
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